CN112337624A

CN112337624A - Fiber separation type autoclaved concrete raw material treatment device

Info

Publication number: CN112337624A
Application number: CN202011107561.3A
Authority: CN
Inventors: 安康
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-10-16
Filing date: 2020-10-16
Publication date: 2021-02-09

Abstract

The invention relates to the field of autoclaved concrete, in particular to a fiber separation type autoclaved concrete raw material processing device. The technical problem of the invention is that: provides a fiber separation type autoclaved concrete raw material processing device. The technical scheme is as follows: a fiber separation type autoclaved concrete raw material processing device comprises an organic bed assembly plate, an elevating workbench, an automatic conveyor belt, a turnover control mechanism, an even crushing mechanism, a grading crushing mechanism and a soaking flotation mechanism; the upper part of the machine tool assembly plate is connected with an elevating workbench. The invention realizes the uniform crushing of the paperless gypsum board with fiber connection inside, so that the paperless gypsum board becomes small crushed blocks connected by the fiber, the strength of the crushed small blocks is reduced, the crushed small blocks are subjected to graded rolling and crushing, finally, a mixture of gypsum powder and fiber is obtained, the fiber is separated by flotation, and the moisture carried in the fiber is separated.

Description

Fiber separation type autoclaved concrete raw material treatment device

Technical Field

The invention relates to the field of autoclaved concrete, in particular to a fiber separation type autoclaved concrete raw material processing device.

Background

The autoclaved aerated concrete block is a porous concrete product prepared by using fly ash, lime, cement, gypsum, slag and the like as main raw materials, adding a proper amount of a gas former, a regulator and a bubble stabilizer, and carrying out the processes of batching, stirring, pouring, standing, cutting, high-pressure steam curing and the like.

At present, in the prior art, waste gypsum boards are usually crushed and ground to obtain gypsum raw materials which are further used for producing autoclaved aerated concrete blocks, a paperless gypsum board exists, the gypsum board is internally reinforced by adopting fiber connection, and the strength of the gypsum board is higher in the process of crushing the gypsum board, if the hard gypsum board is directly added into a crushing mechanism, the gypsum board has larger volume and higher hardness, so that physical damage can be caused to crushing equipment, the service life is shortened, meanwhile, a large number of fiber connections exist in the gypsum board, fibers can be wound into the equipment in the crushing process to influence the normal operation of the equipment, meanwhile, after the crushing is finished, partial gypsum blocks are still connected with the fibers and cannot be directly utilized, the gypsum blocks connected with the fibers also need to be manually sorted and separated, and small gypsum blocks with the fibers cannot be mechanically crushed for the second time due to smaller volume, need artifical hammer chisel to carry out the fragmentation to it, it is big and inefficiency to consume physical power, and partial gypsum piece manpower can't be fragmented, causes the inside gypsum composition utilization ratio of gypsum board low.

In order to solve the problems, a fiber separation type autoclaved concrete raw material processing device is provided.

Disclosure of Invention

In order to overcome the defects that in the prior art, waste gypsum boards are usually crushed and ground to obtain gypsum raw materials which are further used for producing autoclaved aerated concrete blocks, a paperless gypsum board exists, the gypsum board is internally reinforced by fiber connection, the strength of the gypsum board is higher in the process of crushing the gypsum board, if the hard gypsum board is directly added into a crushing mechanism, the physical damage to crushing equipment can be caused due to the larger size and higher hardness of the gypsum board, the service life is shortened, meanwhile, a large number of fiber connections exist in the gypsum board, the fibers can be wound into the equipment in the crushing process to influence the normal operation of the equipment, and meanwhile, after the crushing is finished, part of gypsum blocks are still connected with the fibers and cannot be directly utilized, and the gypsum blocks connected with the fibers also need to be manually sorted and separated, the small gypsum blocks with fibers cannot be mechanically crushed for the second time due to small volume, the small gypsum blocks need to be crushed by a manual hammer chisel, the physical strength is high, the efficiency is low, and part of gypsum blocks cannot be crushed by manpower, so that the utilization rate of gypsum components in the gypsum board is low, and the technical problem of the invention is that: provides a fiber separation type autoclaved concrete raw material processing device.

The technical scheme is as follows: a fiber separation type autoclaved concrete raw material processing device comprises an organic bed assembly plate, an elevating workbench, an automatic conveyor belt, a turnover control mechanism, an even crushing mechanism, a grading crushing mechanism and a soaking flotation mechanism; the upper part of the machine tool assembly plate is connected with an elevating workbench; the upper part of the elevating workbench is connected with an automatic conveyor belt; the upper part of the machine tool assembly plate is connected with a turnover control mechanism; the turning control mechanism is connected with the uniform crushing mechanism; the turning control mechanism is connected with the grading grinding mechanism; the lower part of the grading crushing mechanism is connected with a machine tool collecting plate; the grading crushing mechanism is connected with the soaking flotation mechanism; the grading and crushing mechanism is connected with the elevating workbench; the lower part of the soaking flotation mechanism is connected with a machine tool collecting plate.

Further explaining, the turnover control mechanism comprises a first collecting plate, a first gear carrier, a first telescopic rotating shaft, a first bearing sleeve plate, a first electric push rod, a first bevel gear, a second bevel gear, a first rotating shaft rod, a first bearing seat, a third bevel gear, a second rotating shaft rod, a first flat gear, a propulsion control toothed bar, a first limiting chute plate, an installation collecting frame, a clamping rack, a second electric push rod and a positioning frame; the upper part of the first gathering plate is connected with a first gear rack; the first gear rack is rotationally connected with the first telescopic rotating shaft; the outer surface of the first telescopic rotating shaft is rotatably connected with the first bearing sleeve plate; the first bearing sleeve plate is connected with the first electric push rod; the first electric push rod is connected with the first gear carrier; the outer surface of the first telescopic rotating shaft is fixedly connected with a first bevel gear and a second bevel gear in sequence; the first telescopic rotating shaft is fixedly connected with the first rotating shaft rod; the outer surface of the first rotating shaft rod is rotationally connected with the first bearing seat; the lower part of the first bearing seat is connected with a first gathering plate; the second bevel gear is meshed with the third bevel gear; the axle center of the third bevel gear is fixedly connected with the second rotating shaft rod; the outer surface of the second rotating shaft rod is rotationally connected with the first gear rack; the second rotating shaft rod is fixedly connected with the first flat gear; the upper part of the first flat gear is meshed with the propelling control rack bar; the upper part of the propulsion control rack bar is in sliding connection with the first limiting sliding chute plate; the upper part of the first limiting chute plate is welded with the mounting collecting frame; a clamping rack is arranged below the propulsion control rack rod; the lower part of the clamping rack is connected with a second electric push rod; the second electric push rod is connected with the mounting assembly frame; the mounting collection frame is connected with the positioning frame; the lower part of the mounting collection frame is connected with a first collection plate; the lower part of the first assembly plate is connected with a machine tool assembly plate; the upper part of the first collecting plate is connected with a uniform crushing mechanism; the first rotating shaft rod is connected with the grading crushing mechanism; the mounting collecting frame is connected with the uniform crushing mechanism; the propulsion control toothed bar is connected with the uniform crushing mechanism.

Further explaining, the uniform smashing mechanism comprises a second collecting plate, a first overturning supporting mechanism, a second overturning supporting mechanism, a bearing collecting plate, a flat-placing supporting column, a first elastic telescopic rod, a second elastic telescopic rod, a control bar, a linkage connecting rod, a fixed shaft bracket, an impact smashing ball, an electric pushing column, a limiting plate, a first collecting frame column and a third collecting plate; the upper part of the second collecting plate is sequentially connected with the first overturning supporting mechanism and the second overturning supporting mechanism; the upper part of the first overturning supporting mechanism is connected with the bearing assembly plate; the first overturning supporting mechanism is connected with the first elastic telescopic rod; the second overturning supporting mechanism is connected with the second elastic telescopic rod; the lower part of the bearing assembly plate is connected with a second overturning supporting mechanism; the upper part of the bearing aggregation plate is connected with a flat supporting column; the bearing assembly plate is rotationally connected with the fixed shaft bracket; the outer surface of the second elastic telescopic rod is sleeved with the control strip; the inner side of the control strip is sleeved with the first elastic telescopic rod; the control bar is connected with the linkage connecting rod; the impact crushing ball is arranged above the bearing assembly plate; the upper part of the impact fragmentation ball is connected with an electric pushing column; the outer surface of the electric push column is in sliding connection with the limiting plate; the limiting plate is welded with the first collecting frame column; the upper part of the electric push column is connected with a third collecting plate; the third collecting plate is connected with the first collecting frame column; the lower part of the first collecting frame column is connected with a first collecting plate; the lower part of the second collecting plate is connected with the first collecting plate; the fixed shaft bracket is connected with the mounting assembly bracket; the first elastic telescopic rod is connected with the mounting collection frame; the second elastic telescopic rod is connected with the mounting collection frame; the linkage connecting rod is connected with the propulsion control toothed rod.

Further, the grading crushing mechanism comprises a power motor, a motor mounting frame, a second flat gear, a first crushing roller, a first bearing frame plate, a third flat gear, a second crushing roller, a fourth bevel gear, a third rotating shaft rod, a first driving wheel, a fifth bevel gear, a fourth rotating shaft rod, a second driving wheel, a third driving wheel, a fourth driving wheel, a fifth rotating shaft rod, a second bearing seat, a fourth flat gear, a fifth flat gear, a first crushing roller, a second crushing roller and an inclined slideway plate; the lower part of the power motor is connected with a motor mounting frame through a bolt; an output shaft of the power motor is fixedly connected with the second flat gear; the axle center of the second flat gear is fixedly connected with the first crushing roller; the axle center of the first crushing roller is rotationally connected with the first bearing frame plate; the second flat gear is meshed with the third flat gear; the axle center of the third flat gear is fixedly connected with the second crushing roller; the axle center of the second crushing roller is rotationally connected with the first bearing frame plate; the axle center of the third flat gear is fixedly connected with the fourth bevel gear; the axle center of the fourth bevel gear is fixedly connected with the third rotating shaft rod; the outer surface of the third rotating shaft rod is rotatably connected with the motor mounting frame; the third rotating shaft rod is fixedly connected with the first driving wheel; the fourth bevel gear is meshed with the fifth bevel gear; the axis of the fifth bevel gear is fixedly connected with the fourth rotating shaft rod; the outer surface of the fourth rotating shaft rod is rotatably connected with the motor mounting rack; the outer surface of the fourth rotating shaft rod is fixedly connected with the second driving wheel and the third driving wheel in sequence; the outer ring surface of the third driving wheel is in transmission connection with the fourth driving wheel through a belt; the axle center of the fourth driving wheel is fixedly connected with the fifth rotating shaft rod; the outer surface of the fifth rotating shaft rod is rotatably connected with the second bearing seat; the second flat gear is meshed with the fourth flat gear; the axle center of the fourth flat gear is rotationally connected with the motor mounting rack; the fourth flat gear is meshed with the fifth flat gear; the axis of the fifth flat gear is rotationally connected with the motor mounting rack; the axle center of the fourth flat gear is fixedly connected with the second crushing roller; the axle center of the second crushing roller is rotationally connected with the first bearing frame plate; the axis of the fifth flat gear is fixedly connected with the first crushing roller; the axle center of the first crushing roller is rotationally connected with the first bearing frame plate; an inclined slide way plate is arranged above the first crushing roller; the inclined slideway plate is connected with the elevating workbench; the lower part of the motor mounting frame is connected with a machine tool assembling plate; the lower part of the first bearing frame plate is connected with a machine tool collecting plate; the lower part of the second bearing seat is connected with an elevating workbench; the fifth rotating shaft rod is connected with the first rotating shaft rod; the first driving wheel is connected with the soaking flotation mechanism; the second driving wheel is connected with the soaking flotation mechanism.

Further explaining, the soaking flotation mechanism comprises a fifth driving wheel, a sixth rotating shaft rod, a third bearing seat, a soaking cabin, a water flow power fan blade, a pump frame, a water pump, a water inlet pipe, a bearing mesh plate, a rotating pressing plate, an elastic pressing block, an eccentric wheel disc, a fourth bearing seat, a seventh rotating shaft rod and a sixth driving wheel; the axle center of the fifth driving wheel is fixedly connected with the sixth rotating shaft rod; the outer surface of the sixth rotating shaft rod is rotatably connected with the third bearing seat; the third bearing seat is connected with the soaking cabin; the sixth rotating shaft rod is rotatably connected with the soaking cabin; the sixth rotating shaft rod is fixedly connected with the water flow power fan blade; the soaking cabin is connected with the pump frame; the upper part of the pump frame is connected with a water pump through a bolt; the water pump is connected with the water inlet pipe; the soaking cabin is connected with the bearing mesh plate; the bearing mesh plate is rotationally connected with the rotary pressure plate; the rotary pressing plate is connected with the elastic pressing block; one side of the elastic pressing block close to the rotating pressing plate is provided with an eccentric wheel disc; the eccentric wheel disc is fixedly connected with the seventh rotating shaft rod; the seventh rotating shaft rod is rotationally connected with the fourth bearing seat; the seventh rotating shaft rod is fixedly connected with the sixth driving wheel; the lower part of the soaking cabin is connected with a machine tool collecting plate; the fifth driving wheel is connected with the first driving wheel; the lower part of the fourth bearing seat is connected with a machine tool assembling plate; the sixth driving wheel is connected with the second driving wheel.

Further explaining, the first overturning supporting mechanism comprises a first connecting shaft seat, a first connecting shaft rod, a first collecting shaft column, a second connecting shaft rod, a bending limiting supporting box and a second connecting shaft seat; the first connecting shaft seat is rotationally connected with the first connecting shaft rod; the first connecting shaft rod is rotationally connected with the first collecting shaft column; the first collecting shaft column is rotationally connected with the second connecting shaft rod; the first collecting shaft column is connected with the bending limiting support box; the upper part of the second connecting shaft rod is rotationally connected with the second connecting shaft seat; the lower part of the first connecting shaft seat is connected with a second gathering plate; the upper part of the second connecting shaft seat is connected with a bearing aggregation plate; the bending limit support box is connected with the first elastic telescopic rod.

Further, four flat supporting columns are arranged above the bearing and gathering plate, and the four flat supporting columns are arranged in a square opposite angle mode.

Further, one side of the soaking cabin, which is close to the bearing mesh plate, is provided with a rectangular through opening, and the height of the rectangular through opening is the same as the height of the axis of the water flow power fan blade.

Further, the cross section of the sliding groove above the propulsion control toothed bar and the first limiting sliding groove plate is T-shaped.

The beneficial effects are that: 1. in order to solve the problems that in the prior art, waste gypsum boards are usually crushed and ground to obtain gypsum raw materials which are then used for producing autoclaved aerated concrete blocks, a paperless gypsum board exists, the gypsum board is internally reinforced by adopting fiber connection, the strength of the gypsum board is higher in the process of crushing the gypsum board, if the hard gypsum board is directly added into a crushing mechanism, the size of the gypsum board is larger, the hardness of the gypsum board is larger, physical damage can be caused to crushing equipment, the service life is shortened, meanwhile, a large number of fiber connections exist in the gypsum board, fibers can be wound into the equipment in the crushing process to influence the normal operation of the equipment, and meanwhile, after the crushing is finished, part of gypsum blocks are still connected with the fibers and cannot be directly utilized, and the gypsum blocks connected with the fibers need to be manually sorted and separated, the small gypsum blocks with fibers cannot be mechanically crushed for the second time due to small volume, and are crushed by a manual hammer chisel, so that the physical strength is high, the efficiency is low, and part of gypsum blocks cannot be crushed manually, so that the utilization rate of gypsum components in the gypsum board is low;

2. the turning control mechanism, the uniform crushing mechanism, the grading crushing mechanism and the soaking flotation mechanism are designed, when in use, firstly, a paperless gypsum board to be processed is fixed inside the uniform crushing mechanism, then, an external controller is connected with a power system inside the device, then, the uniform crushing mechanism carries out uniform impact crushing on the paperless gypsum board, then, the turning control mechanism controls the uniform crushing mechanism to turn over and convey the paperless gypsum board which is preliminarily crushed but is connected through internal fibers to the grading crushing mechanism for grading crushing, then, the pulverized paperless gypsum board enters the soaking flotation mechanism to be soaked in water, gypsum powder is settled to the bottom of water, the fibers float on the water surface, then, the floating fibers are separated, and water inside the gypsum board is extruded;

3. the method has the advantages that the paperless gypsum board with fiber connection inside is uniformly crushed, the paperless gypsum board is made into small crushed blocks connected through fibers, the strength of the small crushed blocks is reduced, the small crushed blocks are subjected to classified rolling and crushing, finally, a mixture of gypsum powder and fibers is obtained, the fibers are separated through flotation, and moisture carried inside the fibers is separated.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic perspective view of the turnover control mechanism of the present invention;

FIG. 3 is a schematic perspective view of the homogenizing mechanism of the present invention;

FIG. 4 is a schematic diagram of a first perspective structure of the staged grinding mechanism of the present invention;

FIG. 5 is a schematic diagram of a second perspective structure of the staged grinding mechanism of the present invention;

FIG. 6 is a schematic perspective view of a soaking flotation mechanism of the present invention;

fig. 7 is a schematic perspective view of the first flipping support mechanism according to the present invention.

In the above drawings: 1. a machine tool collecting plate, 2, an elevating workbench, 3, an automatic conveyor belt, 4, a turnover control mechanism, 5, a uniform crushing mechanism, 6, a grading crushing mechanism, 7, a soaking flotation mechanism, 401, a first collecting plate, 402, a first gear carrier, 403, a first telescopic rotating shaft, 404, a first bearing sleeve plate, 405, a first electric push rod, 406, a first bevel gear, 407, a second bevel gear, 408, a first rotating shaft rod, 409, a first bearing seat, 4010, a third bevel gear, 4011, a second rotating shaft rod, 4012, a first flat gear, 4013, a propulsion control toothed bar, 4014, a first limiting sliding groove plate, 4015, an installation collecting frame, 4016, a clamping rack, 4017, a second electric push rod, 4018, a positioning frame, 501, a second collecting plate, 502, a first turnover support mechanism, 503, a second turnover support mechanism, 504, a bearing plate, 505, a support column, 506 and a first elastic flat-laying, 507. a second elastic expansion rod, 508, a control bar, 509, a linkage joint rod, 5010, a fixed shaft bracket, 5011, an impact crushing ball, 5012, an electric pushing column, 5013, a limiting plate, 5014, a first aggregation frame column, 5015, a third aggregation plate, 601, a power motor, 602, a motor mounting bracket, 603, a second flat gear, 604, a first crushing roller, 605, a first bearing frame plate, 606, a third flat gear, 607, a second crushing roller, 608, a fourth bevel gear, 609, a third rotating shaft, 6010, a first transmission wheel, 6011, a fifth bevel gear, 6012, a fourth rotating shaft, 6013, a second transmission wheel, 6014, a third transmission wheel, 6015, a fourth transmission wheel, 6016, a fifth rotating shaft, 6017, a second bearing seat, 6018, a fourth flat gear, 6019, a fifth flat gear, 6020, a first crushing roller, 6021, a second crushing roller, 2, an inclined slideway plate, 701, a sixth transmission wheel, 702, a third rotating shaft, 703. the device comprises a third bearing seat, 704, a soaking cabin, 705, a water flow power fan blade, 706, a pump frame, 707, a water pump, 708, a water inlet pipe, 709, a bearing mesh plate, 7010, a rotating pressure plate, 7011, an elastic pressure block, 7012, an eccentric wheel disc, 7013, a fourth bearing seat, 7014, a seventh rotating shaft rod, 7015, a sixth driving wheel, 50201, a first connecting shaft seat, 50202, a first connecting shaft rod, 50203, a first collecting shaft column, 50204, a second connecting shaft rod, 50205, a bending limiting support box, 50206 and a second connecting shaft seat.

Detailed Description

The above-described scheme is further illustrated below with reference to specific examples. It should be understood that these examples are for illustrative purposes and are not intended to limit the scope of the present application. The conditions used in the examples may be further adjusted according to the conditions of the particular manufacturer, and the conditions not specified are generally the conditions in routine experiments.

Example 1

A fiber separation type autoclaved concrete raw material processing device is shown in figures 1-7 and comprises an organic bed assembly plate 1, an elevating workbench 2, an automatic conveyor belt 3, a turnover control mechanism 4, an even crushing mechanism 5, a grading crushing mechanism 6 and a soaking flotation mechanism 7; the upper part of the machine tool assembly plate 1 is connected with an elevating workbench 2; the upper part of the elevating workbench 2 is connected with an automatic conveyor belt 3; the upper part of the machine tool assembly plate 1 is connected with a turnover control mechanism 4; the turning control mechanism 4 is connected with the uniform crushing mechanism 5; the overturning control mechanism 4 is connected with the grading grinding mechanism 6; the lower part of the grading and crushing mechanism 6 is connected with a machine tool assembling plate 1; the grading and crushing mechanism 6 is connected with the soaking and flotation mechanism 7; the grading and crushing mechanism 6 is connected with the elevating workbench 2; the lower part of the soaking flotation mechanism 7 is connected with a machine tool collecting plate 1.

The working process is as follows: when the fiber separation type autoclaved concrete raw material processing device is used, the device is firstly fixed to a working plane, then is externally connected with a power supply, and is externally connected with a controller, then a paperless gypsum board to be processed is fixed inside the uniform crushing mechanism 5, then a power system inside the device is connected through the external controller, then the uniform crushing mechanism 5 carries out uniform impact crushing on the paperless gypsum board, then the overturning control mechanism 4 controls the uniform crushing mechanism 5 to overturn and transmit the paperless gypsum board which is preliminarily crushed but connected through internal fibers to the inside of the grading crushing mechanism 6 for grading crushing, then the pulverized paperless gypsum board enters the soaking flotation mechanism 7 to be soaked by adding water, gypsum powder is settled to the bottom of water, fibers float on the water surface, then the floating fibers are separated, and the internal water is extruded, so that the uniform crushing of the paperless gypsum board with the fiber connection inside is realized, the paper-free gypsum board is made into small pieces which are connected by fibers, the strength of the small pieces is reduced, the small pieces are subjected to classified rolling and crushing, finally, a mixture of gypsum powder and fibers is obtained, the fibers are separated by flotation, and moisture carried in the fibers is separated.

The overturning control mechanism 4 comprises a first collecting plate 401, a first gear carrier 402, a first telescopic rotating shaft 403, a first bearing sleeve plate 404, a first electric push rod 405, a first bevel gear 406, a second bevel gear 407, a first rotating shaft rod 408, a first bearing seat 409, a third bevel gear 4010, a second rotating shaft rod 4011, a first flat gear 4012, a propelling control toothed rod 4013, a first limiting sliding groove plate 4014, an installation collecting frame 4015, a clamping rack 4016, a second electric push rod 4017 and a positioning frame 4018; the first carrier 402 is connected to the upper side of the first manifold plate 401; the first gear rack 402 is rotatably connected with the first telescopic rotating shaft 403; the outer surface of the first telescopic rotating shaft 403 is rotatably connected with a first bearing sleeve plate 404; the first bearing sleeve plate 404 is connected with a first electric push rod 405; the first electric push rod 405 is connected with the first carrier 402; the outer surface of the first telescopic rotating shaft 403 is fixedly connected with a first bevel gear 406 and a second bevel gear 407 in sequence; the first telescopic rotating shaft 403 is fixedly connected with the first rotating shaft rod 408; the outer surface of the first rotating shaft rod 408 is rotatably connected with the first bearing seat 409; the lower part of the first bearing seat 409 is connected with a first gathering plate 401; the second bevel gear 407 is meshed with the third bevel gear 4010; the axle center of the third bevel gear 4010 is fixedly connected with the second rotating shaft rod 4011; the outer surface of the second rotating shaft rod 4011 is rotatably connected with the first gear carrier 402; the second rotating shaft rod 4011 is fixedly connected with the first flat gear 4012; the upper part of the first flat gear 4012 is meshed with a propulsion control toothed bar 4013; the upper part of the propulsion control rack bar 4013 is in sliding connection with a first limit chute plate 4014; the upper part of the first limiting chute plate 4014 is welded with an installation assembly frame 4015; a clamping rack 4016 is arranged below the propulsion control toothed bar 4013; the lower part of the clamping rack 4016 is connected with a second electric push rod 4017; the second electric push rod 4017 is connected with the mounting assembly frame 4015; the installation collecting frame 4015 is connected with the positioning frame 4018; the lower part of the installation collecting frame 4015 is connected with a first collecting plate 401; the lower part of the first assembly plate 401 is connected with a machine tool assembly plate 1; the upper part of the first collecting plate 401 is connected with a uniform crushing mechanism 5; the first rotating shaft rod 408 is connected with the grading crushing mechanism 6; the installation collecting frame 4015 is connected with the uniform crushing mechanism 5; the propulsion control rack bar 4013 is connected to the homogenizing mechanism 5.

Firstly, the paperless gypsum board is fixed to the inner side of a positioning frame 4018, then the uniform crushing mechanism 5 uniformly crushes the paperless gypsum board, then at this time, a fifth rotating shaft rod 6016 drives a first rotating shaft rod 408 to rotate, then the first rotating shaft rod 408 drives a first telescopic rotating shaft 403 to rotate, then the first telescopic rotating shaft 403 drives a first bevel gear 406 and a second bevel gear 407 to rotate, then the second bevel gear 407 drives a third bevel gear 4010 to rotate, further the third bevel gear 4010 drives a second rotating shaft rod 4011 to rotate, further the second rotating shaft rod 4011 drives a first flat gear 4012 to rotate, then the first flat gear 4012 drives a propulsion control toothed bar 4013 to slide on the inner side of a first limit chute board 4014, further the propulsion control toothed bar 4013 drives a linkage connecting rod 509 to move, namely, the uniform crushing mechanism 5 is driven to overturn and topple over the paperless gypsum board, then the first electric push rod 405 is controlled to be pushed out, the first electric push rod 405 drives the first bearing sleeve plate 404 to move, the first bearing sleeve plate 404 drives the first telescopic rotating shaft 403 to be pushed out, the first telescopic rotating shaft 403 drives the second bevel gear 407 to be disengaged from the third bevel gear 4010, meanwhile, the position where the first bevel gear 406 is engaged with the third bevel gear 4010 is driven, the first bevel gear 406 drives the third bevel gear 4010 to rotate reversely, the third bevel gear 4010 drives the first flat gear 4012 to rotate reversely through the second rotating shaft 4011, the first flat gear 4012 drives the propulsion control toothed bar 4013 to control the linkage connecting bar 509 to reset, and the turnover blanking of the uniformly crushed paperless gypsum board is completed.

The uniform crushing mechanism 5 comprises a second collecting plate 501, a first overturning supporting mechanism 502, a second overturning supporting mechanism 503, a bearing collecting plate 504, a flat supporting column 505, a first elastic telescopic rod 506, a second elastic telescopic rod 507, a control bar 508, a linkage connecting rod 509, a fixed shaft bracket 5010, an impact crushing ball 5011, an electric pushing column 5012, a limiting plate 5013, a first collecting bracket column 5014 and a third collecting plate 5015; the upper part of the second collection plate 501 is sequentially connected with a first overturning supporting mechanism 502 and a second overturning supporting mechanism 503; the upper part of the first overturning supporting mechanism 502 is connected with a bearing collection plate 504; the first flipping support mechanism 502 is connected to a first elastic telescoping rod 506; the second overturning supporting mechanism 503 is connected with the second elastic expansion link 507; the lower part of the bearing and gathering plate 504 is connected with a second overturning and supporting mechanism 503; the upper part of the bearing and gathering plate 504 is connected with a flat supporting column 505; the bearing assembly plate 504 is rotatably connected with the fixed shaft bracket 5010; the outer surface of the second elastic expansion link 507 is sleeved with the control bar 508; the inner side of the control bar 508 is sleeved with the first elastic telescopic rod 506; the control bar 508 is connected with a linkage joint rod 509; impact crushing balls 5011 are arranged above the bearing and gathering plate 504; the upper part of the impact fragmentation ball 5011 is connected with an electric push column 5012; the outer surface of the electric push column 5012 is in sliding connection with the limiting plate 5013; the limiting plate 5013 is welded with the first collecting frame column 5014; the upper part of the electric push column 5012 is connected with a third collecting plate 5015; the third manifold 5015 is connected to the first manifold post 5014; the lower part of the first collecting frame column 5014 is connected with a first collecting plate 401; the lower part of the second collecting plate 501 is connected with the first collecting plate 401; the fixed shaft bracket 5010 is connected with the installation assembly frame 4015; the first elastic telescopic rod 506 is connected with the installation collecting frame 4015; the second elastic expansion link 507 is connected with the mounting assembly frame 4015; the linkage joint rod 509 is connected to the advancing control rack 4013.

Firstly, fixing the paperless gypsum board above a horizontal support column 505, enabling the paperless gypsum board to lean against the inner side of a positioning frame 4018, enabling the paperless gypsum board to be accurately positioned below impact fragmentation balls 5011, then controlling a plurality of electric push columns 5012 to push downwards, further driving the impact fragmentation balls 5011 to impact downwards by the electric push columns 5012, further enabling the impact fragmentation balls 5011 to impact the paperless gypsum board above the horizontal support column 505, further enabling the paperless gypsum board to be impacted and fragmented by the impact fragmentation balls 5011 which are uniformly distributed, at the moment, forming an integral fragmentation paperless gypsum board connected through a limit, then controlling a push control toothed bar 4013 to drive a linkage connecting bar 509 to move towards a direction close to an overturning control mechanism 4, further enabling the linkage connecting bar 509 to drive a first elastic telescopic rod 506 and a second elastic telescopic rod 507 to compress through a control bar 508, and further enabling the first elastic telescopic rod 506 and the second elastic telescopic rod 507 to drive a first overturning support mechanism 502 and a second overturning control bar 507 respectively The second upset supporting mechanism 503 carries out the motion of buckling, and then bears set board 504 and rotate the downward sloping around fixed pedestal 5010, and then the even garrulous paperless gypsum board upset landing of keeping flat support column 505 top to automatic conveyor 3 top, and then automatic conveyor 3 drives the paperless gypsum board motion of this garrulous to pulverize mechanism 6 inside in grades, has accomplished the even garrulous to paperless gypsum board.

The stepped crushing mechanism 6 comprises a power motor 601, a motor mounting frame 602, a second flat gear 603, a first crushing roller 604, a first bearing frame plate 605, a third flat gear 606, a second crushing roller 607, a fourth bevel gear 608, a third rotating shaft rod 609, a first driving wheel 6010, a fifth bevel gear 6011, a fourth rotating shaft rod 6012, a second driving wheel 6013, a third driving wheel 6014, a fourth driving wheel 6015, a fifth rotating shaft rod 6016, a second bearing seat 6017, a fourth flat gear 6018, a fifth flat gear 6019, a first crushing roller 6020, a second crushing roller 6021 and an inclined slideway plate 6022; the lower part of the power motor 601 is connected with a motor mounting frame 602 through bolts; an output shaft of the power motor 601 is fixedly connected with the second flat gear 603; the axle center of the second flat gear 603 is fixedly connected with the first crushing roller 604; the axis of the first crushing roller 604 is rotatably connected to the first bearing frame plate 605; the second pinion 603 meshes with the third pinion 606; the axis of the third gear 606 is fixedly connected with the second crushing roller 607; the axis of the second crushing roller 607 is rotatably connected to the first bearing frame plate 605; the axis of the third bevel gear 606 is fixedly connected with a fourth bevel gear 608; the axis of the fourth bevel gear 608 is fixedly connected with a third rotating shaft 609; the outer surface of the third rotating shaft rod 609 is rotatably connected with the motor mounting bracket 602; the third rotating shaft 609 is fixedly connected with the first driving wheel 6010; the fourth bevel gear 608 meshes with the fifth bevel gear 6011; the axis of the fifth bevel gear 6011 is fixedly connected to a fourth spindle 6012; the outer surface of the fourth rotating shaft 6012 is rotatably connected to the motor mounting bracket 602; the outer surface of the fourth rotating shaft rod 6012 is fixedly connected with a second driving wheel 6013 and a third driving wheel 6014 in sequence; the outer ring surface of the third driving wheel 6014 is in transmission connection with a fourth driving wheel 6015 through a belt; the axle center of the fourth driving wheel 6015 is fixedly connected with the fifth rotating shaft 6016; the outer surface of the fifth rotating shaft 6016 is rotatably connected to the second bearing block 6017; the second spur gear 603 is engaged with the fourth spur gear 6018; the axle center of the fourth flat gear 6018 is rotatably connected with the motor mounting frame 602; the fourth spur gear 6018 meshes with the fifth spur gear 6019; the axis of the fifth spur gear 6019 is rotatably connected to the motor mounting bracket 602; the axle center of the fourth flat gear 6018 is fixedly connected with the second crushing roller 6021; the axis of the second crushing roller 6021 is rotatably connected to the first bearing frame plate 605; the axis of the fifth spur gear 6019 is fixedly connected with the first crushing roller 6020; the axis of the first crushing roller 6020 is rotatably connected to the first bearing frame plate 605; an inclined slide plate 6022 is arranged above the first crushing roller 604; the inclined slide way plate 6022 is connected with the elevating workbench 2; the lower part of the motor mounting frame 602 is connected with a machine tool collecting plate 1; the lower part of the first bearing frame plate 605 is connected with a machine tool collecting plate 1; the lower part of the second bearing seat 6017 is connected with the elevating workbench 2; the fifth spindle 6016 is connected to the first spindle 408; the first driving wheel 6010 is connected with the soaking flotation mechanism 7; the second driving wheel 6013 is connected to the soaking flotation mechanism 7.

First, the power of the power motor 601 is switched on through the external controller, then the power motor 601 drives the second flat gear 603 to rotate, then the second flat gear 603 drives the first crushing roller 604 to rotate, at the same time, the second flat gear 603 drives the third flat gear 606 to rotate, that is, the third flat gear 606 drives the second crushing roller 607 to rotate, at the same time, the second flat gear 603 drives the fourth flat gear 6018 to rotate, that is, the fourth flat gear 6018 drives the second crushing roller 6021 to rotate, the third flat gear 606 drives the fifth flat gear 6019 to rotate, further, the fifth flat gear 6019 drives the first crushing roller 6020 to rotate, then the automatic conveyor belt 3 drives the crushed paperless gypsum plate to fall down and slide down to the inside of the gap between the first crushing roller 604 and the second crushing roller 607 through the inclined chute plate 6022, then the first crushing roller 604 and the second crushing roller 607 rotate oppositely, and then the paperless gypsum board is crushed, and then the crushed paperless gypsum board passes through the gap between the first crushing roller 6020 and the second crushing roller 6021 again, so that the crushed paperless gypsum board particles are powdered, and thus the classified crushing of the paperless gypsum board is completed.

The soaking flotation mechanism 7 comprises a fifth driving wheel 701, a sixth rotating shaft rod 702, a third bearing seat 703, a soaking cabin 704, a water flow power fan blade 705, a pump frame 706, a water pump 707, a water inlet pipe 708, a bearing mesh plate 709, a rotating pressing plate 7010, an elastic pressing block 7011, an eccentric wheel disc 7012, a fourth bearing seat 7013, a seventh rotating shaft rod 7014 and a sixth driving wheel 7015; the axle center of the fifth driving wheel 701 is fixedly connected with the sixth rotating shaft rod 702; the outer surface of the sixth rotating shaft rod 702 is rotatably connected with the third bearing seat 703; the third bearing housing 703 is connected to the immersion chamber 704; the sixth rotating shaft rod 702 is rotatably connected with the soaking cabin 704; the sixth rotating shaft lever 702 is fixedly connected with the water flow power fan blade 705; the soaking chamber 704 is connected with the pump frame 706; the upper part of the pump frame 706 is connected with a water pump 707 through bolts; the water pump 707 is connected with the water inlet pipe 708; the soaking cabin 704 is connected with the bearing mesh plate 709; the bearing mesh plate 709 is rotationally connected with the rotary pressing plate 7010; the rotary pressing plate 7010 is connected with the elastic pressing block 7011; an eccentric wheel disc 7012 is arranged on one side of the elastic pressing block 7011 close to the rotary pressing plate 7010; the eccentric wheel disc 7012 is fixedly connected with the seventh rotating shaft 7014; the seventh rotating shaft 7014 is rotatably connected to the fourth bearing block 7013; the seventh rotating shaft 7014 is fixedly connected with a sixth driving wheel 7015; the lower part of the soaking cabin 704 is connected with a machine tool collecting plate 1; the fifth driving wheel 701 is connected with the first driving wheel 6010; the lower part of the fourth bearing block 7013 is connected with a machine tool assembly plate 1; the sixth driving wheel 7015 is connected to the second driving wheel 6013.

Firstly, sufficient water is pumped into the soaking cabin 704 through a water pump 707 and a water inlet pipe 708, then the obtained mixture of fiber and gypsum powder enters the water in the soaking cabin 704, at the moment, the gypsum powder settles to the bottom of the water, the fiber floats on the water surface, meanwhile, a first driving wheel 6010 drives a fifth driving wheel 701 to rotate, then the fifth driving wheel 701 drives a sixth rotating shaft rod 702 to rotate, the sixth rotating shaft rod 702 drives a water flow power fan blade 705 to rotate to drive the water to flow, then the fiber on the water surface moves towards the direction close to the bearing mesh plate 709 along with the water flow, further, the fiber flows out to the inner side of the bearing mesh plate 709 from the opening of the soaking cabin 704 along with the water flow, at the moment, the fiber with the water is positioned between an elastic pressing block 7011 and the bearing mesh plate 709, meanwhile, a second driving wheel 6013 drives a sixth driving wheel 7015 to rotate, then, the sixth driving wheel 7015 drives a seventh rotating shaft, and then the seventh rotating shaft 7014 drives the eccentric wheel 7012 to rotate, and then the eccentric wheel 7012 rotates to drive the rotating pressing plate 7010 and the elastic pressing block 7011 to rotate towards the direction close to the bearing mesh plate 709, and then the elastic pressing block 7011 and the bearing mesh plate 709 are extruded to be close to each other, so that the moisture in the fiber is extruded out, and the separation of the fiber and the gypsum powder is completed.

The first turning support mechanism 502 includes a first coupling seat 50201, a first coupling rod 50202, a first collecting shaft column 50203, a second coupling rod 50204, a bending limit support box 50205 and a second coupling seat 50206; the first connecting shaft seat 50201 is rotatably connected with the first connecting shaft rod 50202; the first connecting rod 50202 is rotationally connected with the first collecting shaft column 50203; the first collecting shaft column 50203 is rotationally connected with the second connecting shaft rod 50204; the first collecting shaft column 50203 is connected with a bending limit support box 50205; the upper part of the second connecting shaft rod 50204 is rotationally connected with the second connecting shaft seat 50206; the lower part of the first connecting shaft seat 50201 is connected with a second gathering plate 501; the upper part of the second connecting shaft seat 50206 is connected with the bearing collecting plate 504; the bending limit support box 50205 is connected with the first elastic expansion link 506.

Firstly, the linking rod 509 is linked to drive the first elastic expansion link 506 and the second elastic expansion link 507 to contract through the control bar 508, so that the first elastic expansion link 506 contracts to drive the bending limit support box 50205 to move, the bent limit support box 50205 drives the first collecting shaft column 50203 to move, and the first collecting shaft column 50203 drives the first connecting rod 50202 and the second connecting rod 50204 to rotate, and then the vertical state of the first link lever 50202 and the second link lever 50204 is changed, the first link lever 50202 and the second link lever 50204 rotate around the first collecting shaft column 50203, meanwhile, the first coupling rod 50202 and the second coupling rod 50204 rotate around the first coupling seat 50201 and the second coupling seat 50206 respectively, and a straight angle between the first coupling lever 50202 and the second coupling lever 50204 becomes an obtuse angle, that is, the side of the bearing assembly plate 504 close to the graded crushing mechanism 6 is tilted downward, and the tilting and turning control of the bearing assembly plate 504 is completed.

Four flat supporting columns 505 are arranged above the bearing and gathering plate 504, and the four flat supporting columns 505 are arranged in a square and diagonal manner.

So that four horizontal support columns 505 can stably support the paperless gypsum board and do not influence the deformation generated when the paperless gypsum board is crushed.

Wherein, a rectangular through opening is arranged at one side of the soaking cabin 704 close to the bearing mesh plate 709, and the height of the rectangular opening is the same as the height of the axis of the water flow power fan blade 705.

So that the water flow driven by the rotation of the water flow power fan 705 can directly flow out from the rectangular through opening.

The cross section of the sliding groove above the propulsion control toothed bar 4013 and the sliding groove of the first limiting sliding groove plate 4014 is T-shaped.

So that the push control rack bar 4013 does not separate from the connection with the first limit chute plate 4014 due to gravity during the sliding process.

While the disclosure has been shown and described with reference to certain exemplary embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the disclosure as defined by the appended claims and their equivalents. Accordingly, the scope of the present disclosure should not be limited to the above-described embodiments, but should be defined not only by the appended claims, but also by equivalents thereof.

Claims

1. The utility model provides a fibre disconnect-type evaporates presses concrete material processing apparatus, includes organic bed set board, erects high workstation and automatic conveyer belt, characterized by: the device also comprises a turning control mechanism, a uniform crushing mechanism, a grading crushing mechanism and a soaking flotation mechanism; the upper part of the machine tool assembly plate is connected with an elevating workbench; the upper part of the elevating workbench is connected with an automatic conveyor belt; the upper part of the machine tool assembly plate is connected with a turnover control mechanism; the turning control mechanism is connected with the uniform crushing mechanism; the turning control mechanism is connected with the grading grinding mechanism; the lower part of the grading crushing mechanism is connected with a machine tool collecting plate; the grading crushing mechanism is connected with the soaking flotation mechanism; the grading and crushing mechanism is connected with the elevating workbench; the lower part of the soaking flotation mechanism is connected with a machine tool collecting plate.

2. The fiber separation type autoclaved concrete raw material processing device according to claim 1, wherein the overturning control mechanism comprises a first assembling plate, a first gear carrier, a first telescopic rotating shaft, a first bearing sleeve plate, a first electric push rod, a first bevel gear, a second bevel gear, a first rotating shaft rod, a first bearing seat, a third bevel gear, a second rotating shaft rod, a first flat gear, a propulsion control toothed bar, a first limiting chute plate, an installation assembling frame, a clamping rack, a second electric push rod and a positioning frame; the upper part of the first gathering plate is connected with a first gear rack; the first gear rack is rotationally connected with the first telescopic rotating shaft; the outer surface of the first telescopic rotating shaft is rotatably connected with the first bearing sleeve plate; the first bearing sleeve plate is connected with the first electric push rod; the first electric push rod is connected with the first gear carrier; the outer surface of the first telescopic rotating shaft is fixedly connected with a first bevel gear and a second bevel gear in sequence; the first telescopic rotating shaft is fixedly connected with the first rotating shaft rod; the outer surface of the first rotating shaft rod is rotationally connected with the first bearing seat; the lower part of the first bearing seat is connected with a first gathering plate; the second bevel gear is meshed with the third bevel gear; the axle center of the third bevel gear is fixedly connected with the second rotating shaft rod; the outer surface of the second rotating shaft rod is rotationally connected with the first gear rack; the second rotating shaft rod is fixedly connected with the first flat gear; the upper part of the first flat gear is meshed with the propelling control rack bar; the upper part of the propulsion control rack bar is in sliding connection with the first limiting sliding chute plate; the upper part of the first limiting chute plate is welded with the mounting collecting frame; a clamping rack is arranged below the propulsion control rack rod; the lower part of the clamping rack is connected with a second electric push rod; the second electric push rod is connected with the mounting assembly frame; the mounting collection frame is connected with the positioning frame; the lower part of the mounting collection frame is connected with a first collection plate; the lower part of the first assembly plate is connected with a machine tool assembly plate; the upper part of the first collecting plate is connected with a uniform crushing mechanism; the first rotating shaft rod is connected with the grading crushing mechanism; the mounting collecting frame is connected with the uniform crushing mechanism; the propulsion control toothed bar is connected with the uniform crushing mechanism.

3. The fiber separation type autoclaved concrete raw material processing device according to claim 2, wherein the uniform crushing mechanism comprises a second assembling plate, a first overturning supporting mechanism, a second overturning supporting mechanism, a bearing assembling plate, a flat supporting column, a first elastic telescopic rod, a second elastic telescopic rod, a control bar, a linkage connecting rod, a fixed shaft bracket, an impact crushing ball, an electric pushing column, a limiting plate, a first assembling frame column and a third assembling plate; the upper part of the second collecting plate is sequentially connected with the first overturning supporting mechanism and the second overturning supporting mechanism; the upper part of the first overturning supporting mechanism is connected with the bearing assembly plate; the first overturning supporting mechanism is connected with the first elastic telescopic rod; the second overturning supporting mechanism is connected with the second elastic telescopic rod; the lower part of the bearing assembly plate is connected with a second overturning supporting mechanism; the upper part of the bearing aggregation plate is connected with a flat supporting column; the bearing assembly plate is rotationally connected with the fixed shaft bracket; the outer surface of the second elastic telescopic rod is sleeved with the control strip; the inner side of the control strip is sleeved with the first elastic telescopic rod; the control bar is connected with the linkage connecting rod; the impact crushing ball is arranged above the bearing assembly plate; the upper part of the impact fragmentation ball is connected with an electric pushing column; the outer surface of the electric push column is in sliding connection with the limiting plate; the limiting plate is welded with the first collecting frame column; the upper part of the electric push column is connected with a third collecting plate; the third collecting plate is connected with the first collecting frame column; the lower part of the first collecting frame column is connected with a first collecting plate; the lower part of the second collecting plate is connected with the first collecting plate; the fixed shaft bracket is connected with the mounting assembly bracket; the first elastic telescopic rod is connected with the mounting collection frame; the second elastic telescopic rod is connected with the mounting collection frame; the linkage connecting rod is connected with the propulsion control toothed rod.

4. The fiber separation type autoclaved concrete raw material processing device according to claim 3, wherein the step crushing mechanism comprises a power motor, a motor mounting frame, a second flat gear, a first crushing roller, a first bearing frame plate, a third flat gear, a second crushing roller, a fourth bevel gear, a third rotating shaft rod, a first driving wheel, a fifth bevel gear, a fourth rotating shaft rod, a second driving wheel, a third driving wheel, a fourth driving wheel, a fifth rotating shaft rod, a second bearing seat, a fourth flat gear, a fifth flat gear, a first crushing roller, a second crushing roller and an inclined chute plate; the lower part of the power motor is connected with a motor mounting frame through a bolt; an output shaft of the power motor is fixedly connected with the second flat gear; the axle center of the second flat gear is fixedly connected with the first crushing roller; the axle center of the first crushing roller is rotationally connected with the first bearing frame plate; the second flat gear is meshed with the third flat gear; the axle center of the third flat gear is fixedly connected with the second crushing roller; the axle center of the second crushing roller is rotationally connected with the first bearing frame plate; the axle center of the third flat gear is fixedly connected with the fourth bevel gear; the axle center of the fourth bevel gear is fixedly connected with the third rotating shaft rod; the outer surface of the third rotating shaft rod is rotatably connected with the motor mounting frame; the third rotating shaft rod is fixedly connected with the first driving wheel; the fourth bevel gear is meshed with the fifth bevel gear; the axis of the fifth bevel gear is fixedly connected with the fourth rotating shaft rod; the outer surface of the fourth rotating shaft rod is rotatably connected with the motor mounting rack; the outer surface of the fourth rotating shaft rod is fixedly connected with the second driving wheel and the third driving wheel in sequence; the outer ring surface of the third driving wheel is in transmission connection with the fourth driving wheel through a belt; the axle center of the fourth driving wheel is fixedly connected with the fifth rotating shaft rod; the outer surface of the fifth rotating shaft rod is rotatably connected with the second bearing seat; the second flat gear is meshed with the fourth flat gear; the axle center of the fourth flat gear is rotationally connected with the motor mounting rack; the fourth flat gear is meshed with the fifth flat gear; the axis of the fifth flat gear is rotationally connected with the motor mounting rack; the axle center of the fourth flat gear is fixedly connected with the second crushing roller; the axle center of the second crushing roller is rotationally connected with the first bearing frame plate; the axis of the fifth flat gear is fixedly connected with the first crushing roller; the axle center of the first crushing roller is rotationally connected with the first bearing frame plate; an inclined slide way plate is arranged above the first crushing roller; the inclined slideway plate is connected with the elevating workbench; the lower part of the motor mounting frame is connected with a machine tool assembling plate; the lower part of the first bearing frame plate is connected with a machine tool collecting plate; the lower part of the second bearing seat is connected with an elevating workbench; the fifth rotating shaft rod is connected with the first rotating shaft rod; the first driving wheel is connected with the soaking flotation mechanism; the second driving wheel is connected with the soaking flotation mechanism.

5. The fiber separation type autoclaved concrete raw material processing device according to claim 4, wherein the soaking flotation mechanism comprises a fifth driving wheel, a sixth rotating shaft rod, a third bearing seat, a soaking cabin, water flow power fan blades, a pump frame, a water pump, a water inlet pipe, a bearing mesh plate, a rotating pressing plate, an elastic pressing block, an eccentric wheel disc, a fourth bearing seat, a seventh rotating shaft rod and a sixth driving wheel; the axle center of the fifth driving wheel is fixedly connected with the sixth rotating shaft rod; the outer surface of the sixth rotating shaft rod is rotatably connected with the third bearing seat; the third bearing seat is connected with the soaking cabin; the sixth rotating shaft rod is rotatably connected with the soaking cabin; the sixth rotating shaft rod is fixedly connected with the water flow power fan blade; the soaking cabin is connected with the pump frame; the upper part of the pump frame is connected with a water pump through a bolt; the water pump is connected with the water inlet pipe; the soaking cabin is connected with the bearing mesh plate; the bearing mesh plate is rotationally connected with the rotary pressure plate; the rotary pressing plate is connected with the elastic pressing block; one side of the elastic pressing block close to the rotating pressing plate is provided with an eccentric wheel disc; the eccentric wheel disc is fixedly connected with the seventh rotating shaft rod; the seventh rotating shaft rod is rotationally connected with the fourth bearing seat; the seventh rotating shaft rod is fixedly connected with the sixth driving wheel; the lower part of the soaking cabin is connected with a machine tool collecting plate; the fifth driving wheel is connected with the first driving wheel; the lower part of the fourth bearing seat is connected with a machine tool assembling plate; the sixth driving wheel is connected with the second driving wheel.

6. The fiber separation type autoclaved concrete raw material processing device according to claim 5, wherein the first overturning support mechanism comprises a first connecting shaft seat, a first connecting shaft rod, a first collecting shaft column, a second connecting shaft rod, a bending limiting support box and a second connecting shaft seat; the first connecting shaft seat is rotationally connected with the first connecting shaft rod; the first connecting shaft rod is rotationally connected with the first collecting shaft column; the first collecting shaft column is rotationally connected with the second connecting shaft rod; the first collecting shaft column is connected with the bending limiting support box; the upper part of the second connecting shaft rod is rotationally connected with the second connecting shaft seat; the lower part of the first connecting shaft seat is connected with a second gathering plate; the upper part of the second connecting shaft seat is connected with a bearing aggregation plate; the bending limit support box is connected with the first elastic telescopic rod.

7. The fiber separation type autoclaved concrete raw material processing apparatus according to claim 6, wherein four flat supporting columns are arranged above the bearing and gathering plate, and the four flat supporting columns are arranged in a square shape and at opposite angles.

8. The fiber separation type autoclaved concrete raw material processing device according to claim 7, wherein a rectangular through opening is provided at one side of the soaking chamber close to the receiving mesh plate, and the height of the rectangular opening is the same as the height of the axis of the water flow power fan blade.

9. The fiber separation type autoclaved concrete raw material processing apparatus according to claim 8, wherein the cross-sectional shape of the sliding groove above the pushing control rack bar and the first limiting sliding groove plate is T-shaped.